Extracorporeal gas exchange in acute lung injury: step by step towards expanded indications?

Extracorporeal membrane oxygenation (ECMO) is widely accepted as a rescue therapy in patients with acute life-threatening hypoxemia in the course of severe acute respiratory distress syndrome (ARDS). However, possible side effects and complications are considered to limit beneficial outcome effects. Therefore, widening indications with the aim of reducing ventilator induced lung injury (VILI) is still controversial. Consequently, technological progress is an important strategy. Miniaturized ECMO systems are believed to simplify handling and reduce side effects and complications. Mueller and co-workers evaluated such a small-sized device in 60 patients with severe ARDS. They accomplished both the treatment of severe hypoxemia and reduction of VILI, demonstrating feasibility, a moderate rate of severe complications, and a 45% intensive care survival rate. Although neither randomized nor controlled, this study should encourage others to implement such systems in clinical practice. From a strategic perspective, this is another small but useful step towards implementing extracorporeal gas exchange for the prevention of VILI. It is already common sense that the prevention of acute life-threatening hypoxemia usually outweighs the risks of this technique. The next step should be to prove that prevention of life-threatening VILI balances the risks too.


Abstract
Extracorporeal membrane oxygenation (ECMO) is widely accepted as a rescue therapy in patients with acute life-threatening hypoxemia in the course of severe acute respiratory distress syndrome (ARDS). However, possible side eff ects and complications are considered to limit benefi cial outcome eff ects. Therefore, widening indications with the aim of reducing ventilator induced lung injury (VILI) is still controversial. Consequently, technological progress is an important strategy. Miniaturized ECMO systems are believed to simplify handling and reduce side eff ects and complications. Mueller and co-workers evaluated such a small-sized device in 60 patients with severe ARDS. They accomplished both the treatment of severe hypoxemia and reduction of VILI, demonstrating feasibility, a moderate rate of severe complications, and a 45% intensive care survival rate. Although neither randomized nor controlled, this study should encourage others to implement such systems in clinical practice. From a strategic perspective, this is another small but useful step towards implementing extracorporeal gas exchange for the prevention of VILI. It is already common sense that the prevention of acute life-threatening hypoxemia usually outweighs the risks of this technique. The next step should be to prove that prevention of life-threatening VILI balances the risks too.
interhospital transport in 10 of 60 patients without compli cations. All 60 patients were connected according to a predefi ned algorithm when conventional treatment strategies failed to improve gas exchange. Not surprisingly, gas exchange improved signifi cantly due to ECMO treatment and death caused by acute hypoxemia could be prevented entirely. Additionally, tidal volumes were reduced below 6 ml/kg ideal body weight, thereby accomplishing both aims of ECMO treatment, namely prevention of severe hypoxemia and reduction of ventilator induced lung injury (VILI). In summary, an up-to-date strategy of ECMO treatment was combined with up-to-date ECMO technology.
Th erefore, it is astonishing, at fi rst glance, that the survival rate was substantially low compared to other trials [6,8]. However, with regard to severity of illness, organ failure, and age, these results appear acceptable. At least, this aspect can not be further evaluated without randomization and controls.
More interestingly, the authors stated that no lifethreatening complications and side eff ects occurred during the study period. On the other hand, several thrombotic and bleeding complications were reported. Moreover, ECMO implantation was accompanied with resuscitation in two patients and accidental dislocation of a backfl ow cannula caused life-threatening hypoxia in another patient. Th us, although all these patients could be stabilized immediately, it has to be realized that ECMO therapy still is not safe and easy at all and further studies and developments are still needed to further optimize ECMO technology.
However, the new technology presented by Mueller and co-workers is one step towards this. According to their experience it seems justifi ed to implement the use of miniaturized ECMO systems in clinical practice. In particular, this technique off ers practical advantages during transport of ARDS patients. Given the possible advantages of treatment in specialized centers, as has been demonstrated in the CESAR trial, this option should be considered to enable transfer of patients with severe ARDS from peripheral hospitals.
Strictly speaking, scientifi c evidence for ECMO in ARDS patients with acute life-threatening hypoxemia is still lacking. However, due to ethical considerations, randomized controlled trials are diffi cult to plan and perform. Th erefore, the role of ECMO in this clinical situation will probably never be proved and ECMO is and will be accepted as a rescue therapy.
Scientifi c evidence for extracorporeal gas exchange in ARDS patients with life-threatening VILI is also lacking, and scarcely anybody would have ethical concerns about withholding extracorporeal gas exchange therapy from these patients today. Th erefore, randomized controlled trials are indicated to prove this concept with the lowest possible risk of side eff ects and complications. In this regard, the study by Mueller and co-workers is a small but useful step forward.